Category Archives: Applications

CEA-Leti plays a role in the development of the Internet of Things as a provider of key underlying technologies that help its partners take advantage of the opportunities the IoT will offer. These technologies include new sensors, energy-harvesting systems, ultra-low-power communication technologies and ultra-low-power digital processors.

Building on this foundation, the 17th annual LetiDays Grenoble on June 24-25 will expand the conversation with presentations about Internet of Things-augmented mobility, which is revolutionizing the way we interact with appliances, infrastructure and countless common objects that are part of our daily lives.

Another conference theme that includes the IoT and broader markets is Leti’s breakthroughs in silicon technologies, sensors, telecommunications, power management in wearable systems, health applications, transportation and cities of the future. We will focus on how to bring increases in performance, efficiency and security to these fields and markets.

The two-day event will feature more than 40 conferences, many networking opportunities, plus showroom and exhibition halls.

Speakers include:

  • Leti CEO Marie-Noëlle Semeria
  • Suresh Venkatesan, SVP technology development, GLOBALFOUNDRIES
  • Jean-Pierre Cojan, Director, Strategy and Transformation, Safran and
  • Christophe Fourtet, Chief Science Officer and co-founder, SIGFOX. 

In addition, Prof. Alim Louis Benabid will give a keynote address on June 24 at 6 pm. Benabid is a neurosurgeon and board chairman of the Edmond J. Safra Biomedical Research Center Clinatec on the Minatec campus in Grenoble. He has won multiple awards for his pioneering work in the treatment for Parkinson’s disease, including the Albert-Lasker Prize in 2014 and the Breakthrough Prize in Life Sciences in 2015.

Leti also will host technology workshops during the week of June 22:

IC Insights will release its Update to the 2015 IC Market Drivers report in June. The Update includes revisions to IC market conditions and forecasts for the 2015 2018 automotive, smartphone, personal computer and tablet markets, as well as an update to the market for the Internet of Things. This bulletin reviews IC Insights’ 2015 unit shipment forecast for total personal computing unit shipments.

Five years ago, touchscreen tablets began pouring into the personal computing marketplace, stealing growth from standard personal computers and signaling the start of what has been widely described as the “post-PC” era. Led by Apple’s iPad systems, tablet shipments overtook notebook PCs in 2013, and it appeared as if they would surpass total personal computer units (counting both desktop and portable systems) by 2016. However, that scenario no longer seems possible after tablet growth lost significant momentum in 2014 and then nearly stalled out in the first half of 2015 due to the rise in popularity of large-screen smartphones and the lack of interest in new tablets that do not add enough features or capabilities to convince existing users to buy replacements. Consequently, IC Insights has downgraded its forecast for the overall personal computing market, including much lower growth in tablets and continued weakness in standard PCs (Figure 1).

The updated forecast shows total personal computing unit shipments (desktop PCs, notebook PCs, tablets, and Internet/cloud-computing “thin-client” systems) dropping 1 percent in 2015 to 545 million. In the original forecast of the 2015 IC Market Drivers report (MD15), total personal computing system shipments were projected to rise 8 percent in 2015 to 609 million units, followed by a 10 percent increase in 2016 to 670 million. The revised outlook cuts the compound annual growth rate (CAGR) of personal computing unit shipments to 2.1 percent between 2013 and 2018. Total personal computing system shipments are now projected to reach 578 million in 2018.

Worldwide shipments of keyboard-equipped standard PCs (desktops and notebooks) peaked in 2012 at 345 million, but they are expected to decline by a CAGR of -0.5 percent in the 2013-2018 timeperiod. In the updated outlook, tablets are projected to account for 45 percent of total systems sold in 2018 (259 million units) versus the MD15’s original forecast of 57 percent (423 million) that year. Further into the future, tablets are now expected to account for about half of personal computing system shipments with the remaining units being divided between standard PCs and Internet/cloud-centric platforms.

IC Insights June Report

Figure 1

 

Additional details on the IC market for medical and wearable electronic is included in the 2015 edition of IC Insights’ IC Market Drivers—A Study of Emerging and Major End-Use Applications Fueling Demand for Integrated Circuits.  This report examines the largest, existing system opportunities for ICs and evaluates the potential for new applications that are expected to help fuel the market for ICs.

In 2014, the MEMS sector represented an $11.1B business for Si-based devices. According to Yole Développement (Yole) latest MEMS report “Status of the MEMS Industry”, the MEMS industry is preparing to exceed $20B by 2020.

“We have seen different market leaders in the past and the competition is still very open,” said Jean-Christophe Eloy, President & CEO, Yole. “But 2014 will be remembered for the emergence of what could be a future “MEMS Titan”: Robert Bosch (Bosch),” he added.

Under this new analysis entitled, “Status of the MEMS Industry” report Yole proposes a deep understanding of the MEMS markets trends and players dynamics. The More than Moore market research and strategy consulting company announces its 2014 MEMS manufacturers and foundries ranking and proposes an overview of the future game-changers including new devices, disruptive technologies, 300mm wafers, sensor fusion and new markets.

mems market forecast

Bosch’s MEMS revenues have increased by 20 percent to top $1.2B, driven by consumer sales. STMicroelectronics’ revenue is thus now lagging $400M behind. Compared to 2013, the top five companies remain unchanged and together they earn $3.8B, around a third of the total MEMS business. However, Bosch’s dominance is clear, as its revenues now account for around one-third of that figure. Among the 10 or so MEMS titans that are currently sharing most of the MEMS market, Yole distinguishes the “Titans with Momentum” from the “Struggling Titans”

Titans with Momentum group includes Bosch, InvenSense and others.

“Bosch’s case is particularly noteworthy as it is today the only MEMS company in dual markets – namely automotive and consumer – that has the right R&D/production infrastructure,” said Dr Eric Mounier, Senior Technology & Market Analyst, MEMS devices & Technology at Yole.

STMicroelectronics, Texas Instruments, Knowles, Denso and Panasonic are part of the second group, “Struggling Titans.” These companies are currently struggling to have an efficient value growth engine.

A third family is the upcoming “Baby Titans” like Qorvo and Infineon that have grown significantly in the past couple of years and could become serious MEMS players.

Yole has analyzed the three “Brick Walls” players have to overcome to develop a significant MEMS business. The first is to launch a first MEMS product on the market. The second is moving from one to multiple MEMS product lines to diversify a company’s portfolio. The last is the move from being a device maker to a system maker with a successful MEMS business. So far, only Bosch has achieved a very successful transition.

Yole also announces: “New MEMS devices are emerging.” Under its analysis, the consulting company considers gas and chemical sensors. Such devices are based on semiconductor technologies. But MEMS is a further improvement that can reduce size by half or more and also cut costs, thus opening up new opportunities. According to Yole’s analysis, MEMS-based gas sensors will be increasingly used in applications with formfactor/cost issues, particularly in wearables and then consumer applications such as smartphones.

Another example is MEMS micro mirrors. Yole explains: “They are attracting new interest from the market for optical datacom, with Calient achieving impressive growth, or human-machine interfaces, as demonstrated by Intel’s acquisition of Lemoptix.”

Under its analysis on the MEMS & Sensors industry, Yole and its team took the opportunity to exchange with Jeanne Forget, Global Marketing Director, Bosch Sensortec and Dr Frank Schafer, Senior Manager of product management for automotive micro-electro-mechanical sensors (MEMS) at Robert Bosch on the evolution of the MEMS markets and the ability of Bosch, in the last 20 years and for the next decade, to build and maintain its unique leadership on MEMS industry. Full discussion is available on i-micronews.com, MEMS & Sensors news.

SEMI today announced the SEMICON West 2015 technical and business program agenda tackling the most important issues facing the future of semiconductor manufacturing. In addition to the exposition with over 650 exhibitors planned, SEMICON West will feature over 180 total hours of programs —  including free technical, applications and business programs as well as an extensive lineup of exclusive programs. Discounted registration for SEMICON West ends June 5.

Exclusive programs include the three-day Semiconductor Technology Symposium (STS) conference, a comprehensive technology and business conference addressing the key issues driving the future of semiconductor manufacturing and markets. STS is offered as an intensive professional conference, with paid guaranteed classroom-style seating, lunch, and networking breaks. Aligned with the latest inputs from technology roadmaps, sessions at the STS will focus on the significant trends shaping near-term semiconductor technology and market developments in key areas including:

  • Semiconductor Manufacturing: Current Challenges and Future Opportunities for the Supply Chain
  • Adjacent Spaces: Strategies for Executing Expansion into Adjacent Markets
  • Packaging: The Very Big Picture 
  • Packaging: Digital Health and Semiconductor Technology
    • Test Vision 2020 (Automated Test Equipment)
    • Interconnect Technology for High-Performance Computing
    • Making Sense of the Lithography Landscape: Cost and Productivity Issues below 14nm and Path(s) to 5nm
    • Scaling Transistors: HVM Solutions Below 14nm; Getting to 5nm
    • Flexible Hybrid Electronics for Wearable Applications – Challenges/Solutions
    • Interconnect Technology for High-Performance Computing

In addition to the STS conference, SEMICON West continues to feature a full set of complimentary programs, including keynote addresses, executive panels, technical and business sessions.

The Tuesday Keynote Panel includes Jo De Boeck, senior VP and CTO of imec; Mike Campbell, senior VP of Engineering at Qualcomm; and Subashish Mitra, associate professor at Stanford University who will tackle the issue of “Scaling the Walls of sub-14nm Manufacturing.” Doug Davis, senior VP and GM, IoT Group at Intel, will present the Wednesday Keynote.

SEMICON West TechXPOT conference sessions on the exhibition floor are also provided free to exposition attendees. Sessions at the TechXPOTs are developed for engineers, technologists, and business leaders seeking solutions to key technology challenges, exploring cutting-edge and future technology developments and assessing their impact on the semiconductor supply chain. Developed in conjunction with SEMI technical committees, partner organizations, and technologists, the TechXPOT agenda will provide a deeper view of key technology developments and their business impact:

  • What’s Next for MEMS?
  • Automating Semiconductor Test Productivity
  • Emerging Generation Memory Technology: Update on 3D NAND, MRAM and RRAM
  • Materials Session: Contamination Control in the Sub-20nm Era
  • Subsystem and Component Suppliers at Critical Cross Roads to Deliver on Yield and Productivity
  • Equipment and Materials Opportunities for Flexible Hybrid Electronics
  • Packaging Session: Auto Utopia — Gearing up Semiconductor to Turn Dreams to Reality
  • The Evolution of the New 200mm Fab for the Internet of Everything
  • Monetizing the IoT: Opportunities and Challenges for the Semiconductor Sector
  • CMP Technical and Market Trends
  • Factory of the (Near) Future: Using Industrial IoT in Semiconductor Manufacturing Sector
  • Update on Industry Status of 450mm

Other key programs include:

  • Silicon Innovation Forum Conference is a two-day innovation conference that includes a one-day startup/investor forum and a one-day research forum.
  • Sustainable Manufacturing Forum is a three-day event starting on July 13; it delves into issues of Regulatory Compliance, Sustainable Technologies, and Sustainable Supply Chains.
  • “Bulls and Bears,” a session where a panel of technical and financial thought leaders address provocative questions on the state of the microelectronics industry and the outlook for the future.

Discounted registration for SEMICON West 2015 (www.semiconwest.org) through June 5.  Early-bird pricing for the Semiconductor Technology Symposium (STS), Test Vision 2020, and Sustainable Manufacturing Forum (SMF) applies through June 5. Premier sponsors of SEMICON West 2015 include Applied Materials, KLA-Tencor, and Lam Research.

MEMS Industry Group (MIG), the trade association advancing micro-electromechanical systems (MEMS) and sensors across global markets, today announced the creation of a new TSensors division headed by TSensors Summit, Inc. Founder Dr. Janusz Bryzek. MIG’s new division will extend TSensors Summit’s visionary efforts to accelerate a world in which everyone has access to “Abundance” — food, safe water, clean air, healthcare and other vital resources — through the foundational use of sensors and MEMS.

“TSensors has proven itself to be vibrant and incredibly innovative, with initiatives designed to positively change the human experience through the widespread adoption of sensors,” said Karen Lightman, executive director, MEMS Industry Group. “Clearly this is an ambitious goal — but with the success of past TSensors Summits, combined with MIG’s global membership base and organizational structure, I am confident that this goal has a greater potential for realization. We are thrilled to welcome Janusz Bryzek and the TSensors community to MIG. Together we aim to realize the vision of trillions of sensors improving the quality of people’s lives.”

“One of the greatest strengths of TSensors Summit has been our visionary speakers, who have given TED-like talks while outlining an amazing future enabled by new sensor-based systems,” said Dr. Janusz Bryzek, TSensors Summit founder, now heading MIG’s TSensors division. “By joining MEMS Industry Group — with its depth in promoting MEMS commercialization — we will be able to increase the momentum and breadth of TSensors’ initiatives. This will help to both accelerate solutions to major global problems through the use of sensor-based systems as well as to bring unprecedented business opportunities to member companies involved in the design and production of sensor-related products and services.”

TSensors Summit – a MEMS Industry Group® Enterprise will take place on December 9-10, 2015 in Orlando, FL.

Freescale Semiconductor today introduced its Intelligent Sensing Framework (ISF) 2.1, which now includes integration with Freescale’s Processor Expert tool to help create, configure, and generate embedded sensor-based applications for Freescale microcontrollers (MCUs). This integration, together with the framework’s sensor fusion functionality and expanded support for additional sensor types, speeds and simplifies the development of sensor-based solutions for the Internet of Tomorrow – from the connected home and wearables to new medical and connected industrial applications.

A large portion of new, sensor-based Internet of Things (IoT) solutions originate from startup organizations often unfamiliar with the complex process of abstracting, combining and using sensor data. As sensors become increasingly critical to the success of IoT applications, embedded developers need to find ways to quickly and easily integrate multiple streams of sensor data with the MCUs powering their applications.

To address this dynamic, the integration of Freescale’s ISF with Processor Expert development technology provides an easy-to-use tool that streamlines and simplifies the process of abstracting and incorporating multiple sensor data streams into a device or application based on Freescale’s popular families of Kinetis MCUs. Developers can then focus on how the sensor data is used, rather than how it is abstracted and combined.

“The growth of the IoT is enabling services to be created around products that were previously unconnected and unaware of the environments within which they operate,” said James Bates, SVP and GM for Freescale’s Analog and Sensors group. “At the heart of this transformation are intelligent sensor clusters that can deliver information wirelessly and securely. ISF, combined with Processor Expert technology, allows developers to create embedded applications using sensor clusters much more quickly. By removing the burden of abstracting and gathering sensor data, developers can focus on adding their own functionality and IP, driving new innovation for the IoT faster than ever before.”

Leveraging Freescale’s Kinetis MCUs, connectivity solutions, IoT protocols, and security solutions, ISF 2.1 can dramatically reduce time-to-market for sensor-based IoT applications. The framework can be deployed across a wide range of Freescale Kinetis MCUs, provides out-of-box support for the majority of Freescale’s intelligent sensors, and complements Freescale’s broad MCU enablement ecosystem to provide developers a seamless, integrated design environment for incorporating Freescale MCUs and sensors into customers’ embedded system designs.

ISF 2.1 is designed to grow with the Freescale sensor portfolio, and now integrates Freescale’s Sensor Fusion library as a drop-in Processor Expert orientation sensor component. This component enables full configuration of the underlying sensors and fusion algorithms. The framework can deliver sensor data in common engineering units which allow developers to switch between sensors without additional coding to support different device-specific formats. ISF is a key aspect for easily obtaining data to be used in Freescale’s Sensor Data Analytics workflow as demonstrated by the company’s embedded data logger for analytics.

By Zvi Or-Bach, President and CEO of MonolithIC 3D Inc.

Scaling is now bifurcating – some scaling on with 28/22nm, while other push below 14nm.

In his famous 1965 paper Cramming more components onto integrated circuits, Moore wrote: “The complexity for minimum component costs has increased at a rate of roughly a factor of two per year”. Dimensional scaling below 28nm will only increase the ‘component cost’ as we described in Moore’s Law has stopped at 28nm and is detailed in the following tables published recently by IBS.

Fig 1

 

While there is still a strong effort behind dimensional scaling to 14, 10 and 7nm – and possibly even beyond, a new scaling effort is emerging to reduce the ‘component costs’ and increase integration yet still utilize the 28 nm process node. The semiconductor industry is now going through a bifurcation phase.

This new emerging trend of scaling by factors other than dimensional scaling was recognized early-on by Gordon Moore and was detailed in his 1975 famous IEDM paper “Progress in digital integrated electronics.”. In that paper Moore updated the time scaling rate to every two years and suggested the following factors are helping to drive scaling forward:

  1.  “Die size” – “larger chip area”
  2. “Dimension” – “higher density” and “finer geometries”
  3. “Device and circuit cleverness”

A fourth factor should have been added to the list above – improvement in manufacturing efficiency, which ensued from the increase in wafer sizes from 4” to 5” and all the way to the 12” of today, and many other manufacturing improvements.

In the past, all of these factors were aggregated into dimensional scaling as old fabs got obsolete and improvements were implemented predominantly in the new emerging node. Nowadays, as dimensional scaling has reached its diminishing returns phase, we can see a very diverse adaption of technology improvments.

In his keynote presentation at the 2014 Synopsys user group meeting, Art De Geus, Synopsys CEO, presented multiple slides to illustrate the value of Synopsys’ newer tools to improve older node design effectiveness. The following is one of them:

Fig 2

AMD’s recent presentation at ISSCC 2015 clearly illustrates this point by showing device improvements while still staying at the same 28 nm process node, see slide below. As could be seen, major improvements in power, yield, and performance are possible over time without changing the technology node. AMD’s President & CEO Dr. Lisa Su presentation in 2015 Semicon China, reiterated AMD’s technology progress within the same 28nm technology node:

Fig 3

Even more significant would be the adoption of a breakthrough technology. A good example is the SRAM technology developed by Zeno Semiconductor, which has recently been validated on a 28nm process. This new SRAM technology replaces the 6T SRAM bit cell with 1T SRAM (true SRAM – no refresh is needed) providing significant reduction of ‘component costs’ as is illustrated in the following two slides.

Fig 4

Fig 5

This new industry trend was nicely articulated by Kelvin Low of Samsung covered in “Samsung Describes Road to 14nm, FinFETs a challenge, FD-SOI an alternative.” Quoting: “Samsung spent several years developing its 14nm technology and debating which process node it would invest in after 28nm. Low expects that 28nm will still be a popular process node for years to come because of its price …The cost per transistor has increased in 14nm FinFETs and will continue to do so, Low said, so an alternative technology such as 28nm SOI is necessary”. TSMC too is now spending on new R&D efforts to improve their 28 nm as was presented in TSMC 2015 Technology Symposium, introducing new 28nm processes, 28HPC+ and 28ULP. 28HPC+ is for high performance, a speed gain of about 15% for the same leakage, or a reduction of 30-50% in leakage for the same speed. The 28ULP (for ultra-low power) process is for IoT applications with a lower operating voltage of 0.7V (versus 0.9V for 28HPC+). And also new standard cell libraries were developed for this process with 9 and 7 track libraries (compared to 12T/9T before).

“Device and circuit cleverness” as a factor will never stop; however, it is made of a series of individual improvements that will not be enough to sustain a long-term scaling path for the industry. An alternative long-term path will be “Die size” – “larger chip area,” which is effectively monolithic 3D, and manufacturing efficiency, which will have an important role in monolithic 3D.

And who is better to call it than Mark Bohr of Intel? In a recent blog piece “Intel predicts Moore’s Law to last another 10 years” Bohr is quoted predicting “that Moore’s Law will not come to an abrupt halt, but will morph and evolve and go in a different direction, such as scaling density by the 3D stacking of components rather than continuing to reduce transistor size.”

And this is also visible in the marketplace by the industry-wide adoption of 3D NAND devices that Samsung started to mass-produce in 2014, and followed with a second generation 32 layer-stack device this year, and forecasting going to ~ 100 layers, as illustrated in their slide:

Fig 6

 

In the recent webcast “Monolithic 3D: The Most Effective Path for Future IC Scaling,” Dr. Maud Vinet of CEA Leti presented their “CoolCube” monolithic 3D technology, which was followed by our own, i.e., MonolithIC 3D, presentation. An important breakthrough presented by us was a monolithic 3D process flow that does not require changes in transistor-formation process and could be easily integrated by any fab at any process node.

Finally, I’d like to quote Mark Bohr again as we reported in our blog “Intel Calls for 3D IC”: “heterogeneous integration enabled by 3D IC is an increasingly important part of scaling” as was presented in ISSCC 2015.

Fig 7

 

This is illustrated nicely by the following figure presented by Qualcomm in their ISPD ‘15 paper titled “3D VLSI: A Scalable Integration Beyond 2D.”

Fig 8

 

In summary, the general promise of Moore’s Law is not going to end any time soon. Yet it is not going to be the simple brute-force x0.7 dimensional scaling that dominated the industry for the last 5 decades. Quoting Mark Bohr again, it “will morph and evolve and go in a different direction, such as scaling density by the 3D stacking of components rather than continuing to reduce transistor size.”

P.S. –

A good conference to learn about these new scaling technologies is the IEEE S3S ‘15, in Sonoma, CA, on October 5th thru 8th, 2015. CEA Leti is scheduled to give an update on their CoolCube program and three leading researchers from Berkeley, Stanford and Taiwan’s NLA Lab will present their work on advanced monolithic 3D integration technologies.

Intel Corporation today announced plans to develop integrated products with eASIC Corporation that combine processing performance and customizable hardware to meet the increasing demand for custom compute solutions for data centers and the “cloud.” The new parts will enable acceleration of up to two times that of a field programmable gate array (FPGA) for workloads like security and big data analytics while also speeding the time to market for custom application specific integrated circuit (ASIC) development by as much as 50 percent.

The tremendous growth of cloud computing has spurred greater demand for customized chips that make a particular application or workload run faster. To enable this, eASIC plans to integrate its eASIC platform technology with future Intel Xeon processors, providing cloud service providers a highly customized, integrated hardware solution for their particular workload.

eASIC’s technology can increase flexibility and fast-time-to-market when compared to traditional ASICs and increase performance and lower power consumption when compared to FPGAs. By integrating hardware accelerator solutions with the eASIC platform, Intel can deliver much faster and more flexible systems for cloud customers.

“Having the ability to highly customize our solutions for a given workload will not only make the specific application run faster, but also help accelerate the growth of exciting new applications like visual search,” said Diane Bryant, senior vice president and general manager of Intel’s Data Center Group. “This announcement helps broaden our portfolio of customized products to provide our customers with the flexibility and performance they need.”

This collaboration is part of Intel’s strategy to integrate reprogrammable technology with Intel Xeon processors to greatly improve performance, power and cost.

“We believe our eASIC technology has unique characteristics that will benefit cloud service providers to get the most from their applications,” said Ronnie Vasishta, president and chief executive office at eASIC. “The combination of eASIC and Intel technology will help bring break through cost and performance to our customers.”

Samsung Electronics Co., Ltd. today announced the Samsung ARTIK platform to allow faster, simpler development of new enterprise, industrial and consumer applications for the Internet of Things (IoT). ARTIK is an open platform that includes a best-in-class family of integrated production-ready modules, advanced software, development boards, drivers, tools, security features and cloud connectivity designed to help accelerate development of a new generation of better, smarter IoT devices, solutions and services.

“We are providing the industry’s most advanced, open and secure platform for developing IoT products”, said Young Sohn, president and chief strategy officer, Samsung Electronics. “By leveraging Samsung’s high-volume manufacturing, advanced silicon process and packaging technologies, and extensive ecosystem, ARTIK allows developers to rapidly turn great ideas into market leading IoT products and applications.”

The ARTIK Family

All members of the Samsung ARTIK family incorporate unique embedded hardware security technology, on-board memory and advanced processing power in an open platform. Security is also a key element of the advanced software integrated into the platform, along with the ability to connect to the Internet for cloud-based data analytics and enhanced services. As an open platform, Samsung ARTIK can be easily customized for more rapid deployment of IoT devices and the services that can be delivered using them.

The Samsung ARTIK platform comes in a variety of configurations to meet the specific requirements of a wide range of devices from wearables and home automation, to smart lighting and industrial applications. Initial members of the ARTIK family include:

  • ARTIK 1, the smallest IoT module currently available in the industry at 12mm-by-12mm, combines Bluetooth/BLE connectivity and a nine-axis sensor with best-in-class compute capabilities and power consumption. It is specifically designed for low-power, small form-factor IoT applications.
  • ARTIK 5 delivers an outstanding balance of size, power and price-performance and is ideal for home hubs, drones and high-end wearables. It incorporates a 1GHz dual-core processor and on-board DRAM and flash memory.
  • ARTIK 10 delivers advanced capabilities and high-performance to IoT with an eight-core processor, full 1080p video decoding/encoding, 5.1 audio and 2GB DRAM along with 16GB flash memory. The Samsung ARTIK 10 includes Wi-Fi, Bluetooth/BLE and ZigBee connectivity and is designed for use with home servers, media applications, and in industrial settings.

“Industry requirements for IoT devices vary in terms of battery life, computational horse power and form factor,” said Sohn. “With this family of ARTIK offerings, Samsung is directly addressing the needs of the widest range of customers, uses and applications.”

IBM today announced a significant milestone in the development of silicon photonics technology, which enables silicon chips to use pulses of light instead of electrical signals over wires to move data at rapid speeds and longer distances in future computing systems.

For the first time, IBM engineers have designed and tested a fully integrated wavelength multiplexed silicon photonics chip, which will soon enable manufacturing of 100 Gb/s optical transceivers. This will allow datacenters to offer greater data rates and bandwidth for cloud computing and Big Data applications.

“Making silicon photonics technology ready for widespread commercial use will help the semiconductor industry keep pace with ever-growing demands in computing power driven by Big Data and cloud services,” said Arvind Krishna, senior vice president and director of IBM Research. “Just as fiber optics revolutionized the telecommunications industry by speeding up the flow of data — bringing enormous benefits to consumers — we’re excited about the potential of replacing electric signals with pulses of light. This technology is designed to make future computing systems faster and more energy efficient, while enabling customers to capture insights from Big Data in real time.”

Silicon photonics uses tiny optical components to send light pulses to transfer large volumes of data at very high speed between computer chips in servers, large datacenters, and supercomputers, overcoming the limitations of congested data traffic and high-cost traditional interconnects. IBM’s breakthrough enables the integration of different optical components side-by-side with electrical circuits on a single silicon chip using sub-100nm semiconductor technology.

IBM’s silicon photonics chips uses four distinct colors of light travelling within an optical fiber, rather than traditional copper wiring, to transmit data in and around a computing system. In just one second, this new transceiver is estimated to be capable of digitally sharing 63 million tweets or six million images, or downloading an entire high-definition digital movie in just two seconds.

The technology industry is entering a new era of computing that requires IT systems and cloud computing services to process and analyze huge volumes of Big Data in real time, both within datacenters and particularly between cloud computing services. This requires that data be rapidly moved between system components without congestion. Silicon photonics greatly reduces data bottlenecks inside of systems and between computing components, improving response times and delivering faster insights from Big Data.

IBM’s new CMOS Integrated Nano-Photonics Technology will provide a cost-effective silicon photonics solution by combining the vital optical and electrical components, as well as structures enabling fiber packaging, on a single silicon chip. Manufacturing makes use of standard fabrication processes at a silicon chip foundry, making this technology ready for commercialization.

Silicon photonics technology leverages the unique properties of optical communications, which include transmission of high-speed data over kilometer-scale distances, and the ability to overlay multiple colors of light within a single optical fiber to multiply the data volume carried, all while maintaining low power consumption. These characteristics combine to enable rapid movement of data between computer chips and racks within servers, supercomputers, and large datacenters, in order to alleviate the limitations of congested data traffic produced by contemporary interconnect technologies.

Silicon photonics will transform future datacenters

By moving information via pulses of light through optical fibers, optical interconnects are an integral part of contemporary computing systems and next generation datacenters. Computer hardware components, whether a few centimeters or a few kilometers apart, can seamlessly and efficiently communicate with each other at high speeds using such interconnects. This disaggregated and flexible design of datacenters will help reduce the cost of space and energy, while increasing performance and analysis capabilities for users ranging from social media companies to financial services to universities.

Most of the optical interconnect solutions employed within datacenters as of today are based upon vertical cavity surface emitting laser (VCSEL) technology, where the optical signals are transported via multimode optical fiber. Demands for increased distance and data rate between ports, due to cloud services for example, are driving the development of cost-effective single-mode optical interconnect technologies, which can overcome the bandwidth-distance limitations inherent to multimode VCSEL links.

IBM’s CMOS Integrated Nano-Photonics Technology provides an economical solution to extend the reach and data rates of optical links. The essential parts of an optical transceiver, both electrical and optical, can be combined monolithically on one silicon chip, and are designed to work with with standard silicon chip manufacturing processes.

IBM engineers in New York and Zurich, Switzerland and IBM Systems Unit have demonstrated a reference design targeting datacenter interconnects with a range up to two kilometers. This chip demonstrates transmission and reception of high-speed data using four laser “colors,” each operating as an independent 25 Gb/s optical channel. Within a full transceiver design, these four channels can be wavelength multiplexed on-chip to provide 100 Gb/s aggregate bandwidth over a duplex single-mode fiber, thus minimizing the cost of the installed fiber plant within the datacenter.

Further details will be presented by IBM at the 2015 Conference on Lasers and Electro Optics (May 10-15) in San Jose, California, during the invited presentation entitled “Demonstration of Error Free Operation Up To 32 Gb/s From a CMOS Integrated Monolithic Nano-Photonic Transmitter,” by Douglas M. Gill, Chi Xiong, Jonathan E. Proesel, Jessie C. Rosenberg, Jason Orcutt, Marwan Khater, John Ellis-Monaghan, Doris Viens, Yurii Vlasov, Wilfried Haensch, and William M. J. Green.

IBM Research has been leading the development of silicon photonics for more than a decade, announcing a series of technology milestones beginning in 2006. Silicon photonics is among the efforts of IBM’s $3 billion investment to push the limits of chip technology to meet the emerging demands of cloud and Big Data systems.